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High schematic illustration

Fig. (1). Highly schematic illustration of the nervous system in higher animals. Fig. (1). Highly schematic illustration of the nervous system in higher animals.
Figure 10. Highly schematic illustration of fundamental differences between one-and two-strand helices... Figure 10. Highly schematic illustration of fundamental differences between one-and two-strand helices...
Another example of a complex property that can be analyzed and understood by the strategy outlined is the tensile behavior. Although this property is not yet completely understood in molecular terms, sufficient progress has been made that a discussion of this problem is worthwhile. A highly schematic illustration of the ductile deformation in tension of crystalline polymers is given in Fig. 4.49. The initial portion of the deformation, about 2% or 3% strain, is usually reversible. [Pg.302]

Figure B2.5.1 schematically illustrates a typical flow-tube set-up. In gas-phase studies, it serves mainly two purposes. On the one hand it allows highly reactive shortlived reactant species, such as radicals or atoms, to be prepared at well-defined concentrations in an inert buffer gas. On the other hand, the flow replaces the time dependence, t, of a reaction by the dependence on the distance v from the point where the reactants are mixed by the simple transfomiation with the flow velocity vy... Figure B2.5.1 schematically illustrates a typical flow-tube set-up. In gas-phase studies, it serves mainly two purposes. On the one hand it allows highly reactive shortlived reactant species, such as radicals or atoms, to be prepared at well-defined concentrations in an inert buffer gas. On the other hand, the flow replaces the time dependence, t, of a reaction by the dependence on the distance v from the point where the reactants are mixed by the simple transfomiation with the flow velocity vy...
Fig. 9.19 Schematic illustration of an energy surface. A high-temperature molecular dynamics simulation may be ah to ooercome very high energy barriers and so explore conformational space. On minimisation, the appropriate minimum energy conformation is obtained (arrcrws). Fig. 9.19 Schematic illustration of an energy surface. A high-temperature molecular dynamics simulation may be ah to ooercome very high energy barriers and so explore conformational space. On minimisation, the appropriate minimum energy conformation is obtained (arrcrws).
Fig. 3. Two-dimensional schematic illustrating the distribution of Hquid between the Plateau borders and the films separating three adjacent gas bubbles. The radius of curvature r of the interface at the Plateau border depends on the Hquid content and the competition between surface tension and interfacial forces, (a) Flat films and highly curved borders occur for dry foams with strong interfacial forces, (b) Nearly spherical bubbles occur for wet foams where... Fig. 3. Two-dimensional schematic illustrating the distribution of Hquid between the Plateau borders and the films separating three adjacent gas bubbles. The radius of curvature r of the interface at the Plateau border depends on the Hquid content and the competition between surface tension and interfacial forces, (a) Flat films and highly curved borders occur for dry foams with strong interfacial forces, (b) Nearly spherical bubbles occur for wet foams where...
Fig. 3. Schematic illustration of the growth process of a graphitic particle (a)-(d) polyhedral particle formed on the electric arc (d)-(h) transformation of a polyhedral particle into a quasi-spherical onion-like particle under the effect of high-energy electron irradiation in (f) the particle collapses and eliminates the inner empty space[25j. In both schemes, the formation of graphite layers begins at the surface and progresses towards the center. Fig. 3. Schematic illustration of the growth process of a graphitic particle (a)-(d) polyhedral particle formed on the electric arc (d)-(h) transformation of a polyhedral particle into a quasi-spherical onion-like particle under the effect of high-energy electron irradiation in (f) the particle collapses and eliminates the inner empty space[25j. In both schemes, the formation of graphite layers begins at the surface and progresses towards the center.
One leading prototype of a high-temperature fuel cell is the solid oxide fuel cell, or SOFC. The basic principle of the SOFC, like the PEM, is to use an electrolyte layer with high ionic conductivity but very small electronic conductivity. Figure B shows a schematic illustration of a SOFC fuel cell using carbon monoxide as fuel. [Pg.504]

Fig. 2. Schematic illustration of the (110) plane through the atoms in the Si crystal, with labels for relevant high-symmetry positions. Fig. 2. Schematic illustration of the (110) plane through the atoms in the Si crystal, with labels for relevant high-symmetry positions.
FIGURE 19-4 Schematic illustration of the structure and classification of mammalian RGS proteins. All the proteins contain a highly conserved RGS domain that has GAP activity. Most of the proteins contain additional domains that mediate other functions. The figure does not include several other types of homologous proteins, which lack the RGS domain but nevertheless are considered members of the RGS superfamily. [Pg.341]

Fig. 5.9. Schematic illustration (not to scale) of the onion-skin structure in the interior of a highly evolved massive star (25 M0). Numbers along the vertical axis show some typical values of the mass fraction, while those along the horizontal axis indicate temperatures and densities (gmcm-3). Adapted from Kippenhahn and Weigert (1990). Fig. 5.9. Schematic illustration (not to scale) of the onion-skin structure in the interior of a highly evolved massive star (25 M0). Numbers along the vertical axis show some typical values of the mass fraction, while those along the horizontal axis indicate temperatures and densities (gmcm-3). Adapted from Kippenhahn and Weigert (1990).
Figure 2.10 Schematic illustration of the pressure dependence of the chemical potential of a real gas showing deviations from ideal gas behaviour at high pressures. Figure 2.10 Schematic illustration of the pressure dependence of the chemical potential of a real gas showing deviations from ideal gas behaviour at high pressures.
Consider two flasks of gas connected by a small tube. Imagine also that a tap separates them, as seen by the schematic illustration in Figure 4.4. One flask contains hydrogen gas at high pressure p, for example at 2 atm. The other has such a low pressure of hydrogen that it will be called a vacuum. [Pg.151]

Figure 32. Schematic illustrating the possible location and distribution of bulk oxygen flow in LSM under high polarization conditions. (Reprinted with permission from ref 211. Copyright 1995 Elsevier.)... Figure 32. Schematic illustrating the possible location and distribution of bulk oxygen flow in LSM under high polarization conditions. (Reprinted with permission from ref 211. Copyright 1995 Elsevier.)...
Figure 25 Schematic illustration for a system based on energy-dispersive coherent X-ray scatter (CXRS). Observation of the scattered photons is restricted to a fixed angle via a pinhole collimator. The spectrum from a highly energy resolving detector will show peaks at particular energies that are characteristic of the polycrystalline target. Computerized identification techniques can be used to identify the target substance. Figure 25 Schematic illustration for a system based on energy-dispersive coherent X-ray scatter (CXRS). Observation of the scattered photons is restricted to a fixed angle via a pinhole collimator. The spectrum from a highly energy resolving detector will show peaks at particular energies that are characteristic of the polycrystalline target. Computerized identification techniques can be used to identify the target substance.
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